Apparatus for making gravity measurements



May 23, 1939. K. HARTLEY l y APPARATUS FOR MAKING GRAVITY MEASUREMENTS 1934 5 Sheets-Sheet l Filed March 31 i i l i May 23,1939. K. K 'HARTLE- Y 2,159,082

APPARATUS FOR MAKING GRAVITY IIEASUREMENTS Filed Maren 51. i934 5 sheets-sheet 2 May .23 1939- I K. HARTLEY 2,159,082

APPARATUS FOR'MAKING GRAVITY MEASURBHENTS v -Filed March 3l, 1934 5 Sheets-Sheet 3 /00 ,I ,20 9s l d//07 Y? 406 My'23 1939- n K. HA'RTLEY 2,159,082

v APPARATUS FOR MAKING GRAVITY MEASUREMENTS -Fled arch 3l, 1934 5 Sheets-Sheet 4 May 23, 1939. K. HARTLEY- APPARATUS FOR MAKING GRAVITY IEASUREIENTS Filed uarcn 31. 1934 5 Sheets-Sheet 5 lllldlu.

*Iuwwwwwwwwwwwwwwwwwwwwwwmwwwwwwwmwv,` Q 3 2. y I/`u M a 6 m www Patented 'May 2,3, 1939 UNITED STATES l APPARATUS FOR MAKING GRAVITY MEASUREMENTS Kenneth Hartley, Houston, Tex., assignor, by mesne assignments,to Humble Oil & Refining Company, Harris Count Texas y, Tex., a corporation of Application March 31, 1934, Serial No. 718,453

9 Claims. (Cl. 265-14) This invention relates to an apparatus whereby measurements of changes of the force of gravity may be made 'to a very high degree of accuracy. The instrument in accordance with the following .disclosure is capable of making measurements with a precision of one ten-thousandth of a dyne per gram, or approximately one ten-millionth of the total force of gravity.

The apparatus is of the same general character as that described in my Patent 1,898,534, dated Feb. 21, 1933.

It is now well known that the variations of gravitational force are closely connected with the variations of geological structure adjacent the 15- surface of the earth. This fact has been used in geophysical exploration for the location of mineral and oil deposits, the latter being efected by locating salt domes which are generally asl sociated with oil deposits.

It is the object of the present invention to v provide a process and apparatus whereby such `geophysical exploration maybe carried out in a rapid and accuratefashion. Heretofore measurements of variations of the force of gravity have taken very substantial periods of time because of I the necessity, for example, 'of measuring over a long period the vibrations of a pendulum or torsion balance. In accordance with the present invention it is only necessary to attain an equilibrium following an accurate leveling of Yan instrument whereupon the variations of the force' of gravity may be readalmost directly.

Various objects of 'the invention relating primarily to details -of construction and operation whereby great. accuracy anu ready making of observations without loss oi.' time may be effected will be apparent from the following description read/in conjunction with the accompanying drawings, in which: A

1 is a vertical section through the apparatus showing the general assembly ofthe parts, details being omitted for clarity;

Fig. 2 is a vertical section showing the principal operating parts of 'the apparatus in detail;

Figs. 3', 4 and 5 are horizontal sections taken on the planes indicated respectively by the lines .Q -3, 4 4, and 5 5 of Fig. 2;

Fig. 6 is a plan view o! the weighing beam and associated parts; Fig. 7 is a vertical section of the same taken approximately longitudinally of the beam;

Fig. 8 is an end elevation showing certain adjusting means for the optical system; Fig. 9 is a vertical section taken transversely of thev beam;

Fig. 10 is a horizontal section showing certain locking means for the moving parts;

Fig. 1l is a vertical section showing the same subject;

Fig. 12 is a fragmentary view showing certain 5 details of the locking means;

Figs. 13, 14 and l5 are fragmentary views showing 'details of the weighing spring adjusting means;

Fig. 16 is a horizontal section showing pri- 10 marily details of the thermostatic control and indicating devices;

Fig. 17 is a vertical section showing the levels and means whereby they may be observed; and Fig. 18 is a plan view of such means. l5

The instrument comprises an outer casing 2, which may be of any suitable material, which may be supported upon-tripods with suitable adjustment for very accurate leveling. 'Ihe sup-i porting means is not illustrated herein, since it 20 may take a 'conventional form of the type used in supporting other extremely sensitive instruments such as, for example, torsion balances. Desirably the levelingapparatus should be of a type capable of adjusting the level of the in- 25 strument within a small fraction of a minute, Vand in the case of the apparatus herein disclosed it is undesirable to have deviations of more than nve seconds. This extremely accurate leveling is vnecessary to prevent` strains upon the delicate supporting devices which might 'affect the results. Besides, deviations from verticality will Iproduce errors' in determining the gravitational force exerted upon the moving parts.

Because of the extreme sensitivity of the in- 35 strument, insurance m'ust be provided that the temperature of the parts be held constant to within one-thousandth of a degree centigrade. To secure this result, the interior of the outer casing is lined with a heat insulating material 40 which may. take the form of wood or other fibrous material within which'there islocated a housing indicated at 6 provided with a top shown at 8. This housing is a comparatively thick aluminum cylinder which acts as a heat reservoir prevent- 45 ing any rapid fluctuations in temperature within the permissible limits. There is provided in the casing 6 a reservoir ill arranged to contain mercury for the thgrmostatic control. This control will be understood by reference to Fig. 1'6 in con- 50' junction with Fig. l, wherein it will be seen that there is provided inthe housing wall a small bore i2 extending upwardly ,from the reservoir ill and communicating through a suitable coupling with the capillary opening in a thermometer tube I4. 55

The top of this tube is formed with a wen le designed to receive mercury overflow and facilitate initial adjustment. The rising mercury is adapted to form an electrical contact with av rod I8 carried by a screw i9 threaded in the cap of the protecting tube about the tube I4 and extending into the upper portion of the capillary opening. A suitably supported brush 20 bears against the head of the screw I9 and is connected by a wire 22 with one end of the coil 4of a relay 24 whose other end is adapted to be connected .to one teruse of' a spring arrangement indicated at 30- connected to the cover 2 I 0 of the outer housingwhich must be removed for the making of major adjustments. Inside the housing 6 there is located an inner casing 34 of aluminum providedfwith interior ledges on which rests the cap 36 which forms the support for all of the sensitive operating parts of the instrument. .Inasmuch as the casing 34 must be hermetically sealed to prevent buoyancy variations due to changes in atmospheric pressure, the plate 36 is held-.down by the means shown speciiically in Fig. 16, including a rubber tubular gasket pressed into the joint by an annular wedge 35 forced downwardly by a ring 31 which is wedged and locked downwardly by a bayonet joint arrangement indicated at \39. Insulation 32 is provided inthe space between the casing 34 and the housing'6. "Although not shown in Fig. l, insulation is also provided between the plate 36 and the cap 8 of the housing, this insulation being, for example, balsa wood with vertical sight openings for apparatus later referred to. within the casing 34 may be said to contain Vtwo groups of elements, namely, those associated directly with the balance and partaking in the measurement of the changes of gravitational force and those elements which are used to clamp the parts and control them during movements of the apparatus. These two sets of apparatus are in a ,general way kept separate so that inter action is avoided as much as possible, the plate 36 forming a common starting point for the two sets of supports. However, as will be later brought out, the two sets may be connected adjacent the plate 36. The interaction. which must be avoided is primarily thatwhichmight be due to stresses or twisting of the parts resulting from lvertically extending tubes 38, these tubes being preferably clamped to the plate |38 so as to avoid any torsional .strainsl which might result if threaded connections were adopted. 'I'his clamping arrangement is lnot illustrated at the location just mentioned. but is shown elsewhere for the securing of tubular supporting members, for example in Fig. 10,- in connection with thesecu'ring of the lower portions of the tubes 38 to the sup- The working apparatus includedv order to simplify the later discussion of theporting plate 40, whose position is indicated most Vclearly in Figs. 2 and 11. This supporting plate serves to hold the balance poper'and the parts immediately associatedl therewith. Y

Downward extensions 42 of the plate 36 carry tubes 44 to which there is secured'a plate 46, while lower extensions 46 of these tubesfsupport a bracket 50 connected by means of vertical meinbers 5| to a plate 52 which supports vthe clamping means for the weight connected to the beam ofthe instrument. Pillars 54 are carried by the plate 52 and in turn carry at the. r upper ends brackets 56 `which serve as upper bearings for a plurality of rotary members controlling the clamping means.

Upright supports 58 carried by the plate 40 support the base 60 on `which is mounted the beam. This base and the beam which it carries, together with the associated parts, is removable as a unit, being secured to the supports 58 by screws 62. The base 60 and the beam are bifurcated s'o as to be easily removable by horizontal sliding without disturbance to theA spring and weight.

The beam, which is of light material (e. g. magnesium or aluminum alloy) and light construction, is indicated at 64. The beam in a typical instrument Weighs only 1.3y gms. In view of the fact that the fulcrum for the beam imposes one of the major limitations upon thesensitivity of the apparatus if it exerts any appreciable restraint upon its movements, there has been devised the extremely sensitive fulcrum 'arrangement indicated primarily/ in Figs. 6 and 7, which though rugged and capable of withstanding the vibrations imposed when the instrument is transported, nevertheless imposes a minimum of restraint upon such minute angular movementsy of the beam as must be free to occur in obtaining readings. In fact, no measurable restraint was found in an instrument as described herein. vThe beam at the end where the fulcrum is provided is bifurcated and accordingly duplicate' supporting arrangements are provided. Each of these includes a strong spring 68 carried by a vertically adjustable supporting piece 66 secured to the base 60, which spring at its free end carries a very fine ribbon indicated at 10 which is deflected about the convex end of the beam shown a t 12 and is secured to the beam at 14. Y

YAvsecond ribbon indicated at 'I6 is secured at its lower end to the base60 and passes upwardly about the convex end 12 of the beam and is secured thereto at '18.l

By reason of the ypairs of ribbons just described, there is provided an extremely sensitive but balanced and rugged support vfor the'end of the beam. 'I'he radius of curvaturel at 12 is made so great that the stresses in the ribbons' ribbons normally have a tendency toassume a straight position so that in view of their opposite curvature their eiIorts to impart angular rotation to the beam are neutralized tothe extent that they do not tend to turn the beam at all. 'I'he movements of the beam are extremely` slight, and since during an angular movement the radius of curvature at the point of tangency radius curvature of one-sixteenth inch at I2 is are highly satisfactory. With ysuch ribbons a used. 'I'he duplication of the supporting means insures that the beam will be stable against rocking about any longitudinal axis and furthermore there will be no damage done by vibration when the beam is held in clamped position as might occur if, for example, a knife edge support were used.

The beam is connected to the weighing spring by means of a ribbon bridge indicated at 88. the weighing spring which will be referred to hereafter being connected centrally to this bridge. There extends vertically between the bifurcations of the beam 64 aK rod 82 which, at its lower end, carries the weight 84 and at its upper end is secured to the main spring 88. Connected to the rod 82 at 88 there Iis a metallic ribbon 88, for example of molybdenum similar in dimensions to the ribbons I8 and 16, whose lower end is fixed in a stil! spring 82 carried by -the rod so as to maintain the ribbon 88 taut. The ribbon is secured in a slit 84 in the beam, thereby forming the connection between the beam and the spring and weight. 'I'his arrangement, it will be noted, provides 'a connection which is not subject to being readily damaged by vibration ofthe light beam when the weight and spring are clamped. 'I'he location of the center of gravity of the beam is not particularly important, but it is'preferably nea'r 84.

A German-silver weight 84 weighing between 100 and 300 gms. has beenfound most satisfactory. 'I'his weight as well as all of the other moving parts must be non-magnetic to avoid eilects due to terrestrial magnetism.

At the right-hand end of the beam vas viewed in Figs. 6 and 7 there are located mirrors 86 and 81 which form a part ofthe optical indicating system. The connections of the mirrors are somewhat similar and there will be ilrst discussed in detail thev elements forming the mountlng for the mirror 86. 'I'he mirror is connected by a metallic ribbon 88 similar to those mentioned above with the turned end 88 of the beam. It is also connectedA by a pair of similar ribbons |88 located to the left of the ribbon 88 as viewed in Fig. 7 to an arm |82 carried by a horizontally extending pin |84 having a bearing in a block |86, the bearing arrangement being preferably of the double conical type illustrated, so'that a very ilne deilnite positioning of the arm |82 may be insured. 'I'he block |86 is-mounted for vertical sliding movements in a horizontally adjustl able block |81. There is secured to the top of the block |86 by means of a screw ||8 a plate' |88 having a bifurcated end forming a vertical restraint upon a4 screw ||2 into a groove in which the bifurcations extend. '1111s screw ||2 is threaded at-its lower end I4 into the block |81. By turning the screw, ne vertical adjustment of block |86 and consequently of the arm |82 and ribbon |88-is obtained. There is similarly journalled in the plate |88 a screw 6 which is threaded into an arm ||8 carried by the pin |84.

" The turning of this screw serves to provide a ilne adjustment oi'the angular position ofthe arm |82 and hence of the angular position of the mirror 86 about an axis extending longitudinally of the beam. Itv will be noted that the pair of ribbons |88 contribute in securing' a stable adjustment. As will be pointed lout hereafter, this adjustment serves to insure a proper meeting of images of a straight lamp lament in the eld a of a telescope. 'I'he lribbons are conveniently fastened by. drops of lacquer.

The mounting of the mirror 81 is 'similar but reversed. That is, the left-hand ribbon as viewed in Fig. 6 is secured to an arm |28 of the'beam while the right-hand pair of ribbons are secured to an arm |22 -carried by a pin |23 similar to pin |84 and provided with identical adjustments. It will be seen that-these adjustments of the two mirrors serve to universally vary their positions relatively to .each other. The blocks |81A are mounted in guideways |24 in the base 68. They may be clamped in adjusted position by the screw 28 acting through the wedge-shapedl member The spacing of the ribbons 88 and 88 measured longitudinally of the beam is 2 mm. 'I'his insures proper stability.

In spite of the relative ruggedness of the beam supporting means and the provision of a means for clamping the weight and main and weighing springs, it is of importance particularlyl during initial adjustments to clamp the beam in xed position by auxiliary means, this being particularly desirable during initial fixation of the mirrors. For this purpose there are threaded into the base 88 vertically adjustable screws |38 and |32 upon which the beam may be clamped downywardly by means of a spring |34 tensioned against the upper `portion of the beam by a screw |86. A rigid setting of the beam in its desired initial position is thus attained during the period when connections are being made. When the setting is completed, these various adjusting means are withdrawn,l the clamping devices for the springs and weight being sufilcient tov hold the beam during, .-for example, transportation from one position to another in making field observations.

Reference has already been made to the support of the beam through the medium of tubes 88 extending downwardly from the plate |38. Support must be provided for the upper end of the spring 86 from the same plate |38, the suspension being such that the spring will not be elongated by temperature changes when the parts are clamped. This is particularly necessary to avoid'hysteresis eects when the apparatus is not being used fora considerable period and when, consequently, it is not practical to maintainthe temperature asconstant as above indicated. The compensating arrangement will be best-understood from a consideration of Fig. 1. In a general way, it takes the form of the common compensating arrangement used for pendulums. Vertically extending rods |48 supported by the plate |88 carry a plate |42 in which there are secured'upwardly extending tubes |44 housing rods |48 secured to the -tubes-at their upper ends |48. I'he lower ends 'of the rods |48 extending beyon'd the bottoms of the tubes |44 carry al plate |58 in which is secured an upwardly extending tube |52, the upper end of which carries a bracket |84. Threadedv in this bracket is a rotatable rod |56 which is threaded at its lower end into a block |88 vmounted for sliding movement in the lo'wer end of the tube |52 and held from turning by suitable means such as indicated at |88 comprising, for example, a plate car.- ried bythe block |58 perforated to receive a fixed downwardly extending pin. At |68 the spring 86 is connected to the block.

As usual in temperature compensating devices, materialsl having various coeillcients of expansion are used for the formation of the various upright members.` In the present instance these are so chosen that the net change of .position of the lower end of the spring 86 with respect to the beam support due to temperature variathin `ribbons |80.

tions is zero, having regard to all of the parts o f the instrument whose changes in length contribute towards changing the spring length.

In order tol secure a fine adjustment, the threads at the top and bottom of the rod |56 advance in the same direction but with a slightly different pitch. Accordingly, upon `each rotation of the rod, the block |58 will be advanced to an 'extent equal to the diiference in pitch of .the two threads. Inasmuch as this difference in pitch may be made very small even though the pitch v of each thread is sufficiently large to provide a thread of suitable thickness, a very fine adjustment of the position of the upper end of the spring 86 is provided. The spring 86 is preferably, formed of material such as a'tungsten alloy (e. gfa tantalum-tungsten'alloy) having a very low temperature coefcient of elasticity so that the effects of temperature changes are minimized as much as possible. When an ordinary spring undergoes a change in temperature, the elongation not only produces a' change in the material length, but also a twisting of one end relative to theothen In the present apparatus even the slightest twisting would be objectionable.

. This may -be entirely eliminated, however, by

the bridge member 80 previously referred to a weighing spring |62 of very fine wire and'very light construction so'that the change of stress corresponding -to a unit elongation is quite small.

The spring |62 is secured at its upper end to a suspending ,rod |64, ,connected through the medium of a fine ribbon |66 to-one end of a lever |68. The levex` |68 is hinged to a bracket |82 carried by one of the posts 4 4 by means of two At its free end opposite its connection with the rod |64 the lever |68 is connected to a member |84 by means of a flat, thin metallic spring plate |86 which is fitted into slits.

inthe lever |68 and the member |84 as indicated in Figs. 13 and 14. At the top of the member |84 there is affixed an agate bearing |88.l 'In order to provide a suitable guide for themember |84, it is engaged at its upper end by the end of a guide spring |90 fixed to a bracket |92 carried by the bracket |82 previouslyrferred to, the arrangement being such that the member |84 will retain a substantially vertical Aposition during the limited movements imparted to it.

'I'he various connections referred to, namely, |66, |80, |86 and |90 are preferably formed of phosphor bronze having a thickness of the order of '.005 inch. Material of this size provides con-v nection'for the various members of such type that, although a rugged construction is attained, no objectionable restraint is imparted. For the present purpose, these small spring members provide fulcra which cannot get out of adjustment during transportation of the apparatus.

v Engaging the agate bearing |88 there is the lower `end of shaft |98 which` is threaded into a nut |96 carried by the support 42. The shaft |98 passes upwardly through a mercury seal |96, similarto one indicated at 2| 8, hereafter described, which seal |95 serves to cut o communication between the upper and lower sides of the plate moving adjacent to an index marker and serving to indicate by the markings vthereon either the elongation of the spring |62, or directly the effort exerted by this spring upon the beam 64,

which effort is, of course, directly proportional to the elongation. In the apparatus in its preferred f form thisdial is graduatedto indicate directlyr the variations in gravitational pull in millidynes pergram. For thispurpose the dial is provided with 500 divisions, each indicating one-fifth of a millidyne. One complete turn of the dial corresponds to 0.5 mm. elongation of the spring |62. Readings are possible to about 0.1 millidyne, the total range without resetting of Vthe main spring 86 being about 300 millidynes corresponding to three revolutions of the dial or'. elongation of spring |62 by 1.5 mm.

Indication of thelposition of the beam 64 is obtained through an optical system which is illustrated diagrammatically in Fig. l. This optical system may take various forms, but preferably comprises a lamp 202 having a filament' the vertical projection of which is straight, which may be viewed by reflection from the mirrors 96 and 91 by means of a. telescope. The optical system may comprise, for example, the lampv 202 just referred to, a plane plate of glass 203 which is provided merely to form an airtight transparent closurefor the inner chamber, a lens or sysv tem of lenses 204 for rendering parallel the rays beam fromits zero position, there occurring adoubling by reason of the opposite tilting of the 'two mirrors and further amplification by reason ofthe length of the optical system and the magniflcation in the telescope.

Journalled in the plate 36 through the medium of a suitable bushing arrangement which forms in part the means for holding the plate |38 in position, there is a hollow shaft 2|2 connected to a lever 2|4 located above the plate 2|0 and normally closed by means of a screw plug 2|6.k

The tubular form of the shaft 2|2 is provided in yorder` thatupon removal of the plug or cap 2|6 an instrument such as a long screw-driver may -be insertedY to engage the upper end of vthe threaded rod |56 and turn it to adjust the suspension of the spring'86. Normally the tube 2|4 is capped so as to prevent the inward or outward flow of air. from the interior chamber. To permit' the tube to partake of rotary'movementathere is provided a mercury seal 2|8 of conventional type including an. annular cup containing mercury into which there dips an `annular flange carried by the shaft 2|2.

' I'he shaft 2|2, at' its lower'A end, carries a gear 226 which meshes with pinions 222 carried by vertical shafts 224 journalled within the tubes 44. These shafts,'at their lower ends, are coupled to upright rods 228, journalled at their upper ends in an accurate fashion by the provision of double conical bearings in the plate 56, 'and at' their lower ends in bearing openings in the plate 52. An upper nut member 236 has threaded engagement with upper threads on the rods 226 and serves to support, through the medium of screws 232, an upper damping plate 234 having an opening therein through which may extend lthe stem 82 of the weight 84. The screws 232 are threaded into the damping plate 234 and are freely rotatable within the 'nut member- 288, being limited in their downward movement by their heads. In order to lock thedamping plate 234 in fixed position, there are arranged to bear against its upper surface screws 233 tapped into the nut member 238.

'I'he damping plateis arranged to have a very slight clearance with the weight 84 when the apparatusis in use. The air in the slight clearance Aspace provides a damping action to insure against y of the weight. To avoid this, there is provided a slight projection 36 formed from the central portion of the lower face of the plate 234 so that only at this locality may actual contact take place. A satisfactory action is thus attained. The amount of damping action may be controlled by adjustment -of lever 2l4. The clearance to 60 nuts 254 in whichare threaded bearing members effect-substantial damping is of the order of a few thousandths of an inch.

A lower nut member 238, similar to the upper one 238, is likewise threaded upon-the rotatable 'rods 228, the threads engaging with this nut member having a pitch opposite that of the upper threads. The nut member 238 supports; through the medium of screws 240 and 242 corresponding to 233 and 23,2, a lower damping plate 244 which is also provided with a projection fromits damping face as indicated at 246. As will be hereafter more fully pointed out, the plates 284 and 244 not only serve to damp thevibrations of the weight 84, but also serve to clamp it in fixed position during transportation of the instrument.

The central portion of each of the rods 228 carries a pinion 248 meshing with gear segments 249 as indicated in Figs. 10.and12. y These gear segments are guided in oppositely positioned,

.semi-cylindrical blocks 252 supported by posts 258 from the plate 52. In these blocks there are fixed 256 adapted to'be adjusted inwardly and outwardly by, for example, 4the use of a screw-driver.

Extending intoy the journal members 256 so as to be axially slidable therein are pins 262 extending inwardly through openings in the blocks 252 so as to engage, by radial movements, the cylindrical upright central portion of the weight 84. The pins 262 have splined connection with the blocks 252 so as not to rotate therein, and carry obliquely extending plates 263 engageable by cams 268 carried by pinions 258 journalled upon the pins 262 and meshing with racks upon the gear segments 249. Springs 265 normally urge the pins outwardly so as `to disengage them from the weight. The arrangement is such that as the rods 228 are rotated, the pins 262 are forced inwardly to simultaneously engage the weight 84 at the same time that the damping plates 234 and 244 are moved downwardly and upwardly respectively to engage its top and bottom. The weight may thus be clamped against movement in any direction. The adjustments which have been mentioned aresuch that a simultaneous engagement by all of the parts may be effected, preventing any vibration due to impact.

The gear 228 carries downwardly projecting pins 264 shown in Figs. 2 and 8, which are arranged to engage arms 266 ,carried by upright shafts 268 journalled in the plates 42 and 46. Levers 218 at the lower ends of the shafts 268 are arranged to bear upon and press inwardly upright levers 212 pivotedat 213 as indicated in Fig. 2. At their lower ends these rods carry frames 214 on which are adjustably carried upright rods 216 with radially directed inner faces covered vwith leather or other suitabler soft material for engagement with the spring 86. The levers 212 are normally urged outwardly by springs 215. The frames 214 also carry upright members 218 provided with faces adapted to partially embrace and holdin xedfposition the weighing spring |62. All of the various clamping parts are so adjusted that simultaneous clamping of the two springs and the weight 84 take place upon movement of thearm 2i4v connected to the shaft 2I2.

Levls 288 and 282 are mounted on plate 36 and are viewed through suitable glass covered openings in plates 8 and 2|8 and the insulation between these plates with the aid of a mirror 284, suitable provision vfor illumination being made. 'I'hese levels are of a type cable of being read within the limits mentioned abov'e to aid in setting the instrument to the required high degree of accuracy. Additional levels (not shown)` may be provided on the plate 2li! to serve during initial adjustments.

The instrument just described is capable of measuring small differences in the force of gravity with a precision of the order of one ten-thousa-ndth` of adyne per gram, which is about oneten-millionth of the total force of`gravity amounting, in round iigures, approximately to one thousand dynes per gram. A conception of the variation of the force of gravity of the magnitude just mentioned may be gained by considering that a change of one ten-thousandth of a dyne per 'gram amounts to the change inthe force of gravity due to a change in elevation of about one foot. In other words, one division of the scale 265 indicates a change corresponding to an elevation of two feet. f

The zero position to which the parts are brought for the making of a reading is determined in the present instrument by coincidence of the two images ofthe lamp filament as viewed through the eyepiece 208.v It may be pointed' out that this arrangementavoids the necessity for maintaining a iixed point of reference in the telescope; for when the two mirrors are inthe same plane, co-

incidence of the images is obtained no matter how` much the eyepiece and otheroptical parts are displaced. The initial adjustment of the instru- `ment is accordingly primarily concerned with incidence is effected by movements of the slides |06. Proper alignment to'se'cure equal vertical extents of the two images where they neet may be obtained by tilting the mirrors by means of the adjusting screws IIS. It has been found that accurate measurements may be made even while the beam is slightly oscillating by estimating equality of the oscillations about a zero position.

' be prevented.i The eiIects of elastichysteresis rso The optical system in a preferred embodiment of the invention is so arranged that by reason of the optical lever provided by the tilting mirrors there is provided a movement of the image formed in front of the eyepiece 1200 times the corresponding movement of the end of the beam to which the mirrors are connected. The beam ratio is about 1.8; that is, this end of the beam has about 1.8 times the movement of the weight u. In addition, an eyepiece is provided which magniiies the image of the iilament fourteen times. As a result, a total magniiication of the movement of the weightfof about thirty thousand is provided.

Besides this initial adjustment of the optical system, adjustment is also made to insure simultaneous locking of the two springs and the weight 84 so that when locking and release take place during. operation, vibration due to impact will are eliminated by locking the weight and springs in zero position between observations, so that the tension on the spring is never varied by more than the dierence between .the values of the force of gravity between two successive stations. Any hysteresis effect is then only a small 'fraction ofV this amount. 'I'his requires that the weight be locked to-within less than .001 mm. vof the trueA zero position and that the spring may be locked to prevent vibration oi' the convolutions. It is in general unnecessary'to repeat 4the adjustment of the locking means once it has been made.

- In connection with the makingy ofthese initial 'ratus.

' must, of course, be brought to those conditions which must exist during the making of readings. The initial design is made to approximate the desired conditions, the principal object in-view being'r the proper distribution of'load between the main spring 86 and the 'weighing-spring |62. In this instrument, when the parts are in zero position the spring I 62 is adapted to support approxiy -mately one-thousandth of the load imposed by the weight 8l. -Thespring |62, however, cannot be readily designed so that, for example, a change' in length .-of4 1.5 mm. corresponds exactly to a change of 300 millidynes per gram. Calibration is accordingly necessary. In view of the fact that, as pointed out above,the change in gravitational force per unit change in elevation is accumoon at the two times of observation. Suclu calibrating readingsare carried out inthe Vmanner described below adopted for the making of readings in general. v

The obtaining of temperature equilibrium in the instrument isthe primary time-consuming limitation in the matter of making rapid Observaimages. I The vertical adjustment to obtain cotions. It is entirely out of the question to make a temperature'correction rather than maintain the temperature constant. Time is required for the attainment of .temperature equilibrium and any attempt to maintain the temperature only approximately constant outside the range which makes temperature eifects negligible with respect to the accuracy desired would result in the parts `of the instrument being at non-permissible different temperatures. After a long stand-by period through which it may be impractical to maintain current flowing through the heating coil, it is necessary to set the thermostat and then permit the apparatus to heat up for such a period that no drift due to temperature changes can be observed. This heating period following the period of inactivity may consume as much as twenty-four hours. To avoid such delay if the instrument is' only to remain unused for short periods of several days, it is generally advisable to` maintain the heating current flowing continulously. For iield work it isv generally desirable to have thetemperature of the instrument several degrees above the highest expected outside temperature. By the maintenance of the heating current during periods of transportation, suc-- cessive observations may be made at various points without delay and with considerable rapidity.

When the equilibrium temperature is at least approximately attained, it is necessary to set the instrumentso as not toread oil scale or require excessive displacement of the spring |62 from equilibrium position. This setting is attained by changing the length of the spring 86 by rotating the screw v|56 by an instrument passed down through the tube 2|2. After adjustment is ef- Iected, the tube 2|2 is capped so that thereafter external changes in atmospheric pressure will not aifct the instrument by changing the buoyant force upon the moving parts. 'I'he necessity for initial settings in a given region will be apparent by considering the fact that the force of gravity changes with altitude, as abovementioned, and also withlatitude by 'reason of the variations of centrifugalforce with change in distance from the axis of the earths rotation. The latitude changes .tion of the arm 2 Ill'the desired amount of damping and then after vibrations have been suiliciently Adamped out, turn the dial knob 203 until coincidence of the lament images is attained. Successive readings may be made vby moving the dial to Adestroy the equilibrium condition and then bringing the system back to zero position. The adjustment of Adamping takesv care of the elimination of rapid vibrations due to tramo, wind or the like. The effects of the wind are most disturbing to the making or readings inasmuch as.

the swaying of trees causes substantial disturbance of thel earths surface. At the time each tude of the instrument, by surveying ii.' accuracy is desiredand its position as well as the time thel reading is made, there must be noted the altiobservation is made. f extremely accurate observations are lnot necessary, then a barometer .may be used to give an indication of the altitude, correction being, later made for the variations of barometric pressure at sea level. A survey of the locality must be taken into account 'in connection with accurate observations not only to get the exact .altitude -but because of the variation of gravitational force with latitude due tothe centrifugal eilect ofthe rotation oi" the earth. :I'he time must bey noted so that correction maylater be made for the position of the moon'. If the instrument is used in a locality f where there is a substantial tide, correction may measured.

After readings at one station are made, the

also be made to take account of the variation in gravitational pull due to the proximity of a variable large amount of water. It may be noted that the instrument is very carefully leveled for each observation and consequently the local vertical component of the gravitational force is area, it is possible to locate large mineral de-v posits whose density may be greater or less than that of the average over the whole area. The

variations are. in general, due to the upward projection of large masses of heavy mineral de` posits and it has been found that by plotting the variations of gravitational force over a given area proximating the contour of the rock below the a surface may be obtained which corresponds in a general way to the actual contours of the strata. This direct obtaining of a contour apsurface is a very useful result of the direct measurement of the gravity anomaly. A very good picture of the structure may be obtained with very few observations, whereas, if a torsion balance is used, measuring the gravity gradient, the

plot of the gradient must be carefully interpreted and is of such form that unless many readings are made interpretation is difiicult.

One of the primary uses of'thisinstrument is -for the location of salt domes which, as is well known, have generally associated with them oil deposits. The outline'of a salt dome may be determined with considerable accuracy by gravitational observations. Observations of this type have heretofore been made .by the use of torsion balances or pendulums. Readings ofv such instruments, however, are quite diflicult and require long periods of time. At most, readings at about three stations per day can be made by the use of the torsion balance, while by the use of a pendu- `lum even a greater amount of time is required to make an observation. By the use of the present instrument, three or more observations lat different stations can be made in an hour and the results readily corrected to a given level and interpreted. It will be obvious, therefore, .that a given area maybe covered in far less time than by the use of the otherwellknown instrument.

What I claim and desire to protect by Letters Patent is: u

1. A measuring instrument of the character described comprising a mass, means indicative of the position of the mass, a spring for exerting a major vertical effort upon said mass, a second spring for exerting an additional minor vertical eort upon said mass to bring the mass to a determinable position, means whereby the effort exerted by the second spring maybe determined, means for locking the mass and springs in a zero posivtion, and supporting devices, said devices comprising separate supporting elements for the locking means and the mass and a common memlber, said supporting elements being joined only at the common member.

2. A measuring y-instrument of the 4character described comprising a mass, means indicative of the position of the'mass, a spring for exerting a major vertical eiiort upon said mass, a second spring for exerting an additional minor vertical eiiort upon said mass to bring the mass to a determinable position,4 means -whereby the eort exerted by the second spring may be determined, and means `for elongating the rst mentioned spring comprising a member connected to the first spring, and a differential screw threaded into a xed support andv also into said member.

3. A measuring instrument of the character described comprising a mass, `means indicative of the position of the mass, a spring for Iexerting a major vertical eifort upon said mass, ay second spring for exerting an additional minor vertical effort upon said mass to bring the `mass to a determinable position, and means for varying the tension of the second spring comprising a lever connected thereto, a'spring member connected to lthe lever, and adjustable means bearing'upon the spring member for varying the position of the lever.

4. A measuring instrument of the character described comprising a mass, means indicative of the position of the mass, a spring for exerting a major vertical eiort upon said mass, a second spring for exerting an additional minor vertical eiort upon'said mass to bring the mass to a determinable position, and means for varying the tension of the second spring comprising a lever connected thereto and adjustable means for varying the position of the lever, said lever being supported by a resilient metallic ribbon.

5. A measuring instrument of the character i described comprising a mass, means indicative of the. position of the mass, a spring for exerting a major vertical effort upon said mass, a second spring for exerting an additional minor vertical effort upon'sa-d mass to bring the mass to a determinable position, means whereby the effort exerted by the second spring may be determined, a hermetically sealed enclosure for said mass and springs, and an operating device extending through a liquid seal whereby adjustments of the aforementioned devices in the enclosure may be effected from the outside without distributing such sealed condition.

6.`A measuring instrument of the character described comprising a mass, means indicative of the position of the mass, a spring for exerting a.

major vertical effort upon said mass, a second spring for exerting an additional minor vertical effort upon said mass to bring the mass to a de- A terminable position,- means whereby the eiort .I exerted b y the second springmay be determined,

a hermetically sealed enclosure for said mass and springs including a mercury seal, and means whereby adjustments of the aforementioned devices in the enclosure may be effected from the outside without disturbing such sealed condition, said last named means comprising at least one shaft passing through the mercury seal.

7. A measuring instrument of the character described comprising a mass, means indicative of the position of the mass, a spring' for exerting a.

major vertical effort upon said mass, alsecond spring for exerting an additional minor vertical effort upon said mass to bring the mass to a determinable position, means whereby the eiort exerted by the second spring may be determined,

and means for clamping the mass in its zero position, said meansengaging the mass simultaneously at several points to avoid motion by reason of impact.

8. A measuring instrument of the character described comprising a mass, means indicative of the position, of the mass, a spring for exerting a major vertical effort upon said mass. a second spring for exerting an additional minor vertical effort upon said mass to bring the mass to a determinable position, means whereby the effort erted by the second spring may be determined,`

means for clamping the mass in its zero position, and means for clamping both of said springs simultaneously with the' clamping of the mass. I

.KENNETH HAR'HEY. 

